// Copyright (c) 2011-present, Facebook, Inc. All rights reserved. // This source code is licensed under both the GPLv2 (found in the // COPYING file in the root directory) and Apache 2.0 License // (found in the LICENSE.Apache file in the root directory). #include "util/timer.h" #include "db/db_test_util.h" namespace ROCKSDB_NAMESPACE { class TimerTest : public testing::Test { public: TimerTest() : mock_env_(new MockTimeEnv(Env::Default())) {} protected: std::unique_ptr mock_env_; #if defined(OS_MACOSX) && !defined(NDEBUG) // On some platforms (MacOS) pthread_cond_timedwait does not appear // to release the lock for other threads to operate if the deadline time // is already passed. This is a problem for tests in general because // TimedWait calls are a bad abstraction: the deadline parameter is // usually computed from Env time, but is interpreted in real clock time. // Since this test doesn't even pretend to use clock times, we have // to mock TimedWait to ensure it yields. void SetUp() override { ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->DisableProcessing(); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->ClearAllCallBacks(); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->SetCallBack( "InstrumentedCondVar::TimedWaitInternal", [&](void* arg) { uint64_t* time_us = reinterpret_cast(arg); if (*time_us < mock_env_->RealNowMicros()) { *time_us = mock_env_->RealNowMicros() + 1000; } }); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->EnableProcessing(); } #endif // OS_MACOSX && !NDEBUG const uint64_t kSecond = 1000000; // 1sec = 1000000us }; TEST_F(TimerTest, SingleScheduleOnceTest) { const int kIterations = 1; uint64_t time_counter = 0; mock_env_->set_current_time(0); InstrumentedMutex mutex; InstrumentedCondVar test_cv(&mutex); Timer timer(mock_env_.get()); int count = 0; timer.Add( [&] { InstrumentedMutexLock l(&mutex); count++; if (count >= kIterations) { test_cv.SignalAll(); } }, "fn_sch_test", 1 * kSecond, 0); ASSERT_TRUE(timer.Start()); // Wait for execution to finish { InstrumentedMutexLock l(&mutex); while(count < kIterations) { time_counter += kSecond; mock_env_->set_current_time(time_counter); test_cv.TimedWait(time_counter); } } ASSERT_TRUE(timer.Shutdown()); ASSERT_EQ(1, count); } TEST_F(TimerTest, MultipleScheduleOnceTest) { const int kIterations = 1; uint64_t time_counter = 0; mock_env_->set_current_time(0); InstrumentedMutex mutex1; InstrumentedCondVar test_cv1(&mutex1); Timer timer(mock_env_.get()); int count1 = 0; timer.Add( [&] { InstrumentedMutexLock l(&mutex1); count1++; if (count1 >= kIterations) { test_cv1.SignalAll(); } }, "fn_sch_test1", 1 * kSecond, 0); InstrumentedMutex mutex2; InstrumentedCondVar test_cv2(&mutex2); int count2 = 0; timer.Add( [&] { InstrumentedMutexLock l(&mutex2); count2 += 5; if (count2 >= kIterations) { test_cv2.SignalAll(); } }, "fn_sch_test2", 3 * kSecond, 0); ASSERT_TRUE(timer.Start()); // Wait for execution to finish { InstrumentedMutexLock l(&mutex1); while (count1 < kIterations) { time_counter += kSecond; mock_env_->set_current_time(time_counter); test_cv1.TimedWait(time_counter); } } // Wait for execution to finish { InstrumentedMutexLock l(&mutex2); while(count2 < kIterations) { time_counter += kSecond; mock_env_->set_current_time(time_counter); test_cv2.TimedWait(time_counter); } } ASSERT_TRUE(timer.Shutdown()); ASSERT_EQ(1, count1); ASSERT_EQ(5, count2); } TEST_F(TimerTest, SingleScheduleRepeatedlyTest) { const int kIterations = 5; uint64_t time_counter = 0; mock_env_->set_current_time(0); InstrumentedMutex mutex; InstrumentedCondVar test_cv(&mutex); Timer timer(mock_env_.get()); int count = 0; timer.Add( [&] { InstrumentedMutexLock l(&mutex); count++; if (count >= kIterations) { test_cv.SignalAll(); } }, "fn_sch_test", 1 * kSecond, 1 * kSecond); ASSERT_TRUE(timer.Start()); // Wait for execution to finish { InstrumentedMutexLock l(&mutex); while(count < kIterations) { time_counter += kSecond; mock_env_->set_current_time(time_counter); test_cv.TimedWait(time_counter); } } ASSERT_TRUE(timer.Shutdown()); ASSERT_EQ(5, count); } TEST_F(TimerTest, MultipleScheduleRepeatedlyTest) { uint64_t time_counter = 0; mock_env_->set_current_time(0); Timer timer(mock_env_.get()); InstrumentedMutex mutex1; InstrumentedCondVar test_cv1(&mutex1); const int kIterations1 = 5; int count1 = 0; timer.Add( [&] { InstrumentedMutexLock l(&mutex1); count1++; if (count1 >= kIterations1) { test_cv1.SignalAll(); } }, "fn_sch_test1", 0, 2 * kSecond); InstrumentedMutex mutex2; InstrumentedCondVar test_cv2(&mutex2); const int kIterations2 = 5; int count2 = 0; timer.Add( [&] { InstrumentedMutexLock l(&mutex2); count2++; if (count2 >= kIterations2) { test_cv2.SignalAll(); } }, "fn_sch_test2", 1 * kSecond, 2 * kSecond); ASSERT_TRUE(timer.Start()); // Wait for execution to finish { InstrumentedMutexLock l(&mutex1); while(count1 < kIterations1) { time_counter += kSecond; mock_env_->set_current_time(time_counter); test_cv1.TimedWait(time_counter); } } timer.Cancel("fn_sch_test1"); // Wait for execution to finish { InstrumentedMutexLock l(&mutex2); while(count2 < kIterations2) { time_counter += kSecond; mock_env_->set_current_time(time_counter); test_cv2.TimedWait(time_counter); } } timer.Cancel("fn_sch_test2"); ASSERT_TRUE(timer.Shutdown()); ASSERT_EQ(count1, 5); ASSERT_EQ(count2, 5); } TEST_F(TimerTest, AddAfterStartTest) { const int kIterations = 5; InstrumentedMutex mutex; InstrumentedCondVar test_cv(&mutex); // wait timer to run and then add a new job SyncPoint::GetInstance()->LoadDependency( {{"Timer::Run::Waiting", "TimerTest:AddAfterStartTest:1"}}); SyncPoint::GetInstance()->EnableProcessing(); mock_env_->set_current_time(0); Timer timer(mock_env_.get()); ASSERT_TRUE(timer.Start()); TEST_SYNC_POINT("TimerTest:AddAfterStartTest:1"); int count = 0; timer.Add( [&] { InstrumentedMutexLock l(&mutex); count++; if (count >= kIterations) { test_cv.SignalAll(); } }, "fn_sch_test", 1 * kSecond, 1 * kSecond); // Wait for execution to finish uint64_t time_counter = 0; { InstrumentedMutexLock l(&mutex); while (count < kIterations) { time_counter += kSecond; mock_env_->set_current_time(time_counter); test_cv.TimedWait(time_counter); } } ASSERT_TRUE(timer.Shutdown()); ASSERT_EQ(kIterations, count); } TEST_F(TimerTest, CancelRunningTask) { constexpr char kTestFuncName[] = "test_func"; mock_env_->set_current_time(0); Timer timer(mock_env_.get()); ASSERT_TRUE(timer.Start()); int* value = new int; *value = 0; SyncPoint::GetInstance()->DisableProcessing(); SyncPoint::GetInstance()->LoadDependency({ {"TimerTest::CancelRunningTask:test_func:0", "TimerTest::CancelRunningTask:BeforeCancel"}, {"Timer::WaitForTaskCompleteIfNecessary:TaskExecuting", "TimerTest::CancelRunningTask:test_func:1"}, }); SyncPoint::GetInstance()->EnableProcessing(); timer.Add( [&]() { *value = 1; TEST_SYNC_POINT("TimerTest::CancelRunningTask:test_func:0"); TEST_SYNC_POINT("TimerTest::CancelRunningTask:test_func:1"); }, kTestFuncName, 0, 1 * kSecond); port::Thread control_thr([&]() { TEST_SYNC_POINT("TimerTest::CancelRunningTask:BeforeCancel"); timer.Cancel(kTestFuncName); // Verify that *value has been set to 1. ASSERT_EQ(1, *value); delete value; value = nullptr; }); mock_env_->set_current_time(1); control_thr.join(); ASSERT_TRUE(timer.Shutdown()); } TEST_F(TimerTest, ShutdownRunningTask) { constexpr char kTestFunc1Name[] = "test_func1"; constexpr char kTestFunc2Name[] = "test_func2"; mock_env_->set_current_time(0); Timer timer(mock_env_.get()); SyncPoint::GetInstance()->DisableProcessing(); SyncPoint::GetInstance()->LoadDependency({ {"TimerTest::ShutdownRunningTest:test_func:0", "TimerTest::ShutdownRunningTest:BeforeShutdown"}, {"Timer::WaitForTaskCompleteIfNecessary:TaskExecuting", "TimerTest::ShutdownRunningTest:test_func:1"}, }); SyncPoint::GetInstance()->EnableProcessing(); ASSERT_TRUE(timer.Start()); int* value = new int; *value = 0; timer.Add( [&]() { TEST_SYNC_POINT("TimerTest::ShutdownRunningTest:test_func:0"); *value = 1; TEST_SYNC_POINT("TimerTest::ShutdownRunningTest:test_func:1"); }, kTestFunc1Name, 0, 1 * kSecond); timer.Add([&]() { ++(*value); }, kTestFunc2Name, 0, 1 * kSecond); port::Thread control_thr([&]() { TEST_SYNC_POINT("TimerTest::ShutdownRunningTest:BeforeShutdown"); timer.Shutdown(); }); mock_env_->set_current_time(1); control_thr.join(); delete value; } TEST_F(TimerTest, AddSameFuncNameTest) { mock_env_->set_current_time(0); Timer timer(mock_env_.get()); ASSERT_TRUE(timer.Start()); int func_counter1 = 0; timer.Add([&] { func_counter1++; }, "duplicated_func", 1 * kSecond, 5 * kSecond); int func2_counter = 0; timer.Add([&] { func2_counter++; }, "func2", 1 * kSecond, 4 * kSecond); // New function with the same name should override the existing one int func_counter2 = 0; timer.Add([&] { func_counter2++; }, "duplicated_func", 1 * kSecond, 5 * kSecond); timer.TEST_WaitForRun([&] { mock_env_->set_current_time(1); }); ASSERT_EQ(func_counter1, 0); ASSERT_EQ(func2_counter, 1); ASSERT_EQ(func_counter2, 1); timer.TEST_WaitForRun([&] { mock_env_->set_current_time(6); }); ASSERT_EQ(func_counter1, 0); ASSERT_EQ(func2_counter, 2); ASSERT_EQ(func_counter2, 2); ASSERT_TRUE(timer.Shutdown()); } } // namespace ROCKSDB_NAMESPACE int main(int argc, char** argv) { ::testing::InitGoogleTest(&argc, argv); return RUN_ALL_TESTS(); }